A. R. Glenn

Constructs for insertional mutagenesis, transcriptional signal localization and gene regulation studies in root nodule and other bacteria

Cassettes have been developed that contain an antibiotic resistance marker with and without a promoterless gusA reporter gene. The nptII (encoding kanamycin resistance) or aacCI (encoding gentamicin resistance) genes were equipped with the tac promoter (Ptac) and the trpA terminator (TtrpA) and then cloned between NotI sites to construct the CAS-Nm (Ptac-nptII-TtrpA) and CAS-Gm (Ptac/PaacCI-aacCI-TtrpA) cassettes. The markers were also cloned downstream to a modified promoterless Escherichia coli gusA gene (containing TGA stop codons in all three reading frames prior to its RBS and start codon) to construct the CAS-GNm (gusA-Ptac-nptII-TtrpA) or CAS-GGm (gusA-Ptac/PaacCI-aacCI-TtrpA) cassettes. Cassettes containing the promoterless gusA create type I fusions with a target DNA sequence to detect transcriptional activity. The promoterless gusA gene has also been cloned into a broad-host-range IncP1 plasmid. This construct will enable transcriptional activity to be monitored in different genetic backgrounds. Each cassette was cloned as a NotI fragment into the NotI site of a pUT derivative to construct four minitransposons. The mTn5-Nm (containing Ptac-nptII-TtrpA) and mTn5-Gm (containing Ptac/PaacCI-aacCI-TtrpA) minitransposons have been constructed specifically for insertional inactivation studies. The minitransposons mTn5-GNm (containing gusA-Ptac-nptII-TtrpA) and mTn5-GGm (containing gusA-Ptac/PaacCI-aacCI-TtrpA) can be used for transcription signal localization or insertional inactivation. The TAC-31R and TAC-105F primers can be used to sequence DNA flanking both sides of CAS-Nm, CAS-Gm, mTn5-Nm and mTn5-Gm. The WIL3 and TAC-105F primers can be used to sequence DNA flanking both sides of CAS-GNm, CAS-GGm, mTn5-GNm and mTn5-GGm. The specific application of these constructs to generate acid- or nodule-inducible fusions is presented. The new constructs provide useful tools for insertional mutagenesis, transcriptional signal localization and gene regulation studies in the root nodule bacteria and possibly other gram-negative bacteria.

Acid tolerance in Rhizobium meliloti strain WSM419 involves a two-component sensor-regulator system

An acid-sensitive mutant, TG5-46, derived from Rhizobium meliloti WSM419 by Tn5 mutagenesis, fails to grow below pH 6.0 whereas the parent strain grows at pH 5.7. The DNA sequence of a 2.2 kb rhizobial DNA region flanking Tn5 in TG5-46 contains two open reading frames, ORF1 (designated actS) and ORF2 (designated actR), having high similarity to the sensor-regulator pairs of the two-component systems involved in signal transduction in prokaryotes. Insertion of an omega interposon into actS in R. meliloti WSM419 resulted in an acid-sensitive phenotype. A DNA fragment from the wild-type complemented the acid-sensitive phenotype of RT295 (ActS-) and TG5-46 (ActR-), while fragments containing only actR or actS complemented TG5-46 and RT295, respectively. The presence of multiple copies of actR complemented not only TG5-46 but also RT295. Cloning DNA upstream from actR and actS into a broad-host-range lacZ expression vector and measuring beta-galactosidase activities showed that both genes are constitutively expressed regardless of the external pH. Genomic DNA from all strains of R. meliloti, but no other bacteria tested, hybridized with an actRS probe at high stringency. These data implicate a two-component sensor-regulator protein pair in acid tolerance in R. meliloti and suggest their involvement in pH sensing and/or response by these bacteria.

Succinate Uptake by Free-living and Bacteroid Forms of Rhizobium leguminosarum

Free-living cells of Rhizobium leguminosarum possess a constitutive succinate uptake system. Bacteroids isolated from nodules of Pisum sativum also showed immediate uptake of succinate. In both cases the uptake of [14C] succinate appeared to be dependent on an energized membrane. Fumarate, malate and several succinate analogues were also transported via the succinate system. One or both of the carboxyl groups of the succinate molecule must be free in order to be recognized by the carrier. Glucose had effects on the uptake or metabolism of succinate.

Siderophore and organic acid production in root nodule bacteria

Nineteen strains of root nodule bacteria were grown under various iron regimes (0.1, 1.0 and 20 μM added iron) and tested for catechol and hydroxamate siderophore production and the excretion of malate and citrate. The growth response of the strains to iron differed markedly. For 12 strains (Bradyrhizobium strains NC92B and 32H1, B. japonicum USDA110 and CB1809, B. lupini WU8, cowpea Rhizobium NGR234, Rhizobium meliloti strains U45 and CC169, Rhizobium leguminosarum bv viciae WU235 and Rhizobium leguminosarum bv trifolii strains TA1, T1 and WU95) the mean generation time showed no variation with the 200-fold increase in iron concentration. In contrast, in Bradyrhizobium strains NC921, CB756 and TAL1000, B. japonicum strain 61A76 and R. leguminosarum bv viciae MNF300 there was a 2–5 fold decrease in growth rate at low iron. R. meliloti strains WSM419 and WSM540 showed decreased growth at high iron.All strains of root nodule bacteria tested gave a positive CAS (chrome azurol S) assay for siderophore production. No catechol-type siderophores were found in any strain, and only R. leguminosarum bv trifolii T1 and bv viciae WU235 produced hydroxamate under low iron (0.1 and 1.0 μM added iron).Malate was excreted by all strains grown under all iron regimes. Citrate was excreted by B. japonicum USDA110 and B. lupini WU8 in all iron concentrations, while Bradyrhizobium TAL1000, R. leguminosarum bv viciae MNF300 and B. japonicum 61A76 only produced citrate under low iron (0.1 and/or 1.0 μM added iron) during the stationary phase of growth.

Properties of organic acid utilization mutants of Rhizobium leguminosarum strain 300

Summary: Mutants of Rhizobium leguminosarum 300 which were unable to utilize one or more organic acids as growth substrates were obtained by Tn5 mutagenesis. Mutant strain MNF3080 was defective in dicarboxylate transport and was unable to grow on succinate. Strain MNF3085 was defective in phosphoenolpyruvate carboxykinase and hence could not carry out gluconeogenesis. This strain did not grow on pyruvate, succinate, glutamate or arabinose but grew on glucose and on glycerol. Strain MNF3075 was unable to utilize pyruvate; the biochemical lesion in this mutant was not identified. MNF3085 and MNF3075 were symbiotically effective. MNF3080 nodulated peas, but the nodules were ineffective in N2 fixation and displayed morphological abnormalities. These data support previous findings which suggest that utilization of exogenous dicarboxylates is essential for effective nodule development by R. leguminosarum.

The uptake and hydrolysis of disaccharides by fast-and slow-growing species of Rhizobium

Slow growing strains of rhizobia appear to lack both uptake systems and catabolic enzymes for disaccharides. In the fast-growing strains of rhizobia there are uptake mechanisms and catabolic enzymes for disaccharide metabolism. In Rhizobium leguminosarum WU 163 and WU235 and R. trifolii WU290, sucrose and maltose uptake appears to be constitutive whereas in R. meliloti WU60 and in cowpea Rhizobium NGR234 uptake of these disaccharides is inducible. There is evidence that there are at least two distinct disaccharide uptake systems in fast-growing rhizobia, one transporting sucrose, maltose and trehalose and the other, lactose. Disaccharide uptake is via an active process since uptake is inhibited by azide, dinitrophenol and carbonyl cyanide m-chlorophenylhydrazone but not by arsenate. Bacteroids of R. leguminosarum WU235 and R. lupini WU8 are unable to accumulate disaccharides.

ActP controls copper homeostasis in Rhizobium leguminosarum bv. viciae and Sinorhizobium meliloti preventing low pH-induced copper toxicity

Two ‘calcium‐irreparable’ acid‐sensitive mutants were identified after mutagenizing Rhizobium leguminosarum bv. viciae and Sinorhizobium meliloti with Tn5. Each mutant contains a single copy of the transposon which, inserted within the actP gene, prevents expression of a P‐type ATPase that belongs to the CPx heavy metal‐transporting subfamily. Here, we show that both actP‐knockout mutants show sensitivity to copper; omission of this heavy metal from low pH‐buffered media restores acid tolerance to these strains. Furthermore, complementation of the mutant phenotype requires only the actP gene. An actP–gusA fusion in R. leguminosarum was transcriptionally regulated by copper in a pH‐dependent manner. Downstream to actP in both organisms is the hmrR gene that encodes a heavy metal‐responsive regulator (HmrR) that belongs to the merR class of regulatory genes. Insertional inactivation of hmrR abolished transcriptional activation of actP by copper ions and increased the basal level of its expression in their absence. These observations suggest that HmrR can regulate actP transcription positively and negatively. We show that copper homeostasis is an essential mechanism for the acid tolerance of these root nodule bacteria since it prevents this heavy metal from becoming overtly toxic in acidic conditions.

The adaptive acid tolerance response in root nodule bacteria and Escherichia coli

Root nodule bacteria and Escherichia coli show an adaptive acid tolerance response when grown under mildly acidic conditions. This is defined in terms of the rate of cell death upon exposure to acid shock at pH 3.0 and expressed in terms of a decimal reduction time, D. The D values varied with the strain and the pH of the culture medium. Early exponential phase cells of three strains of Rhizobium leguminosarum (WU95, 3001 and WSM710) had D values of 1, 6 and 5 min respectively when grown at pH 7.0; and D values of 5, 20 and 12 min respectively when grown at pH 5.0. Exponential phase cells of Rhizobium tropici UMR1899, Bradyrhizobium japonicum USDA110 and peanut Bradyrhizobium sp. NC92 were more tolerant with D values of 31, 35 and 42 min when grown at pH 7.0; and 56, 86 and 68 min when grown at pH 5.0. Cells of E. coli UB1301 in early exponential phase at pH 7.0 had a D value of 16 min, whereas at pH 5.0 it was 76 min. Stationary phase cells of R. leguminosarum and E. coli were more tolerant (D values usually 2 to 5-fold higher) than those in exponential phase. Cells of R. leguminosarum bv. trifolii 3001 or E. coli UB1301 transferred from cultures at pH. 7.0 to medium at pH 5.0 grew immediately and induced the acid tolerance response within one generation. This was prevented by the addition of chloramphenicol. Acidadapted cells of Rhizobium leguminosarum bv. trifolii WU95 and 3001; or E. coli UB1301, M3503 and M3504 were as sensitive to UV light as those grown at neutral pH.

Exchange of metabolites across the peribacteroid membrane in pea root nodules

Summary Bacteroids surrounded by an intact peribacteroid membrane were isolated anaerobically from pea root nodules. When peribacteroid units were incubated for 30 min with [14C]malate as the sole C substrate, 12 % of the label recovered in the reaction mixture was in the amino acid fraction. This proportion was increased three-fold when unlabelled glutamate was supplied as an additional substrate. With [14C]glutamate as the primary substrate, practically all of the recovered label remained in the amino acid fraction of the reaction mixture with or without unlabelled malate as additional substrate. The results indicate an exchange of metabolites across the peribacteroid membrane and suggest transaminase activity associated with the peribacteroid units of pea.

Symbiotic and competitive properties of motility mutants of Rhizobium trifolii TA1

Non-motile mutants of Rhizobium trifolii defective in either flagellar synthesis or function were isolated by transposon Tn5 mutagenesis. they were indistinguishable from motile control strains in growth in both laboratory media and in the rhizosphere of clover roots. When each non-motile mutant was grown together with a motile strain in continuous culture, the numbers of motile and non-motile organisms remained in constant proportion, implying that their growth rates were essentially identical. When inoculated separately onto clover roots, the mutants and wildtype did not differ significantly in the number of nodules produced or in nitrogen fixing activity. However, when mixtures of equal numbers of mutant and wild-type cells were inoculated onto clover roots, the motile strain formed approximately five times more nodules than the flagellate or non-flagellate, non-motile mutants, suggesting that motility is a factor in competition for nodule formation.